Influence of spin dynamics of defects on weak localization in paramagnetic 2D metals

Abstract

Spin-flip scattering of charge carriers in metals with magnetic defects leads to the low-temperature saturation of the decoherence time, τ, of electrons at the value comparable to their spin relaxation time, τs. In two-dimensional (2D) conductors such a saturation can be lifted by an in-plane magnetic field, B, which polarizes spins of scatterers without affecting orbital motion of free carriers. Here, we show that in 2D conductors with substantially different values of the g-factors of electrons (ge) and magnetic defects (gi), the decoherence time τ(B) (reflected by the curvature of magnetoconductance) displays an anomaly: it first gets shorter, decaying on the scale B /|gi-ge|μB τs, before becoming longer at higher values of B.